Direct-Manufactured Duct Interconnects

ABSTRACT

A method for forming a duct interconnect generally includes providing a digital model of a first duct structure and a second duct structure, the first duct structure including a first duct section having a passage for conveying a substance and an interconnect component moveably and captively coupled to the duct section. The second duct structure includes a second duct structure and a second interconnect component. The process includes forming, via a direct manufacturing procedure (e.g., stereolithography), a physical model of the first duct and second structures in accordance with the digital models, wherein the interconnect component has a locked and unlocked state, and wherein the unlocked state corresponds to a predetermined compressive force between the first duct structure and a second duct structure.

TECHNICAL FIELD

The present invention generally relates to duct systems and, moreparticularly, to duct system interconnects incorporating integralcaptive components.

BACKGROUND

Due to tight space requirements in aircraft and other vehicles, asubstantial amount of time and energy is required to maintain partsburied under other subsystem and structures. Duct sections and the likeare traditionally secured using worm clamps, Wiggins connectors, V-Bandclamps and other such connection schemes. Actuation of these componentsrequires a significant amount of space (i.e., a “clear volume” ofsurrounding space perpendicular to the duct surface) for a wrench,ratchet, or other specialized tool.

To address this issue, some duct interconnect schemes incorporate one ormore captured components—i.e., locking components whose movement islimited or restrained by the duct itself. Such captured components areextremely expensive to manufacture in short production runs, and thehigh degree of detail required for a good lock is not obtainable throughtraditional lay-up or rotational molding processes. Similarly, injectionmolding, while sufficient for producing highly-detailed terminationstructures, is not capable of producing in-situ captured components.

Furthermore, known captured components are often configured as simplethreaded collars that interface with a mating female threaded ductsegment. While easy to actuate, such systems are undesirable in that thelocking force between the interconnected duct segments is highlyvariable, and greatly depends upon the amount of torque applied duringassembly. This variability is unsatisfactory in certain contexts,including military and aircraft applications.

Accordingly, there is a need for interconnect methods that provideadvanced locking geometries with known locking force and improvedclearance for actuation. Furthermore, other desirable features andcharacteristics of the present invention will become apparent from thesubsequent detailed description and the appended claims, taken inconjunction with the accompanying drawings and the foregoing technicalfield and background.

BRIEF SUMMARY

In general, the present invention provides duct structures including oneor more captive components formed via a direct manufacturingtechnique—e.g., selective laser sintering or the like. The invention maybe embodied in one form by a method for forming a duct interconnectincluding: providing a digital model of a first duct structure, thefirst duct structure including a first duct section having a passage forconveying a substance, and an interconnect component moveably andcaptively coupled to the duct section; providing a digital model of asecond duct structure having a second interconnect component; thenforming, via a direct manufacturing procedure, a physical model of thefirst and second duct structures in accordance with respective digitalmodels. In a locked state, a sealing force between the first and secondduct structures is substantially equal to a predetermined value.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will hereinafter be described in conjunction withthe following drawing figures, wherein like numerals denote likeelements, and

FIG. 1 is a conceptual cross-sectional view of a duct system inaccordance with one embodiment of the invention;

FIGS. 2-4 depict various isometric views of an exemplary duct system;and

FIG. 6 shows an isometric overview of a duct structure in accordancewith one embodiment;

FIG. 7 shows an example locking mechanism in accordance with oneembodiment; and

FIG. 8 depicts a locking force between mating interconnect structures.

DETAILED DESCRIPTION

The following detailed description is merely exemplary in nature and isnot intended to limit the invention or the application and uses of theinvention. Furthermore, there is no intention to be bound by anyexpressed or implied theory presented in the preceding technical field,background, brief summary or the following detailed description. Itshould be appreciated that any processing steps described as beingperformed by a computer system, microprocessor, or software may in factbe realized by any number of hardware, software, and/or firmwarecomponents configured to perform the specified functions. For the sakeof brevity, conventional techniques related to direct manufacturing,rapid prototyping, and computer modeling need not be described in detailherein.

In general, the present invention relates to a duct interconnect systemfabricated using a direct-manufacturing process, such as selective lasersintering (SLS), wherein the interconnects include one or more captivecomponents that are easy for a user to actuate and which have apredetermined sealing force when in a locked state.

Referring to the conceptual diagram shown in FIG. 1, a duct connectionsystem in accordance with one embodiment generally includes twodirect-manufactured duct structures configured to be removeablyinterconnected—i.e., a duct structure 100 and a mating duct structure101. Duct structure 100 includes a first duct section 104 having apassage 102 for conveying a substance (e.g., a water, gas, or solid, notshown), and an interconnect component 110 moveably and captivity coupledto duct section 104. Similarly, second duct structure 101 includes asecond duct section 124 having a passage 122 and an interconnectcomponent 120 (which may be fixedly or moveably attached to section 124)configured to enter a locked state when connected to interconnectcomponent 110.

Interconnect component 110 is captively coupled to duct section 104 inthat its relative movement is restricted—e.g., through a reduction indegrees of freedom and/or limitation in movement range. Suchcaptively-coupled parts may be configured in a number of ways. In oneembodiment, two collar stops (106, 108) are incorporated into ductsection 104, and interconnect component 110 includes a collar (shownconceptually as component 110 itself) configured to seat between collarstops 106 and 108. In one embodiment, interconnect structure 110 isrotateably and translationally coupled to duct section 104 within aspatial range defined by collar stops 106 and 108.

A particular embodiment is depicted in FIGS. 2-5, where FIGS. 2 and 4show front and back isometric views of a duct connection system in thelocked position, and FIGS. 3 and 5 show front and back views of a ductconnection system prior to connection. As shown (referring to FIG. 2),duct structure 100 includes a generally circular duct section 204 and aninterconnect structure including a collar 208 that can rotate freelywith respect to duct section 204. Collar 208 also translates along theduct within a range defined by a collar stop 206 and a second collarstop not visible in FIG. 2 (collar stop 207, shown in FIG. 5).

In the illustrated embodiment, each of the interconnect components alsoincludes one or more ergonomic grips 212 and 210 that allow a human toeasily rotate collar 208 while holding grips 210 in place. As shown,grips 210 rotate into place and are stopped by grips 212. A secondarylocking mechanism is provided by fixing grips 212 to grips 210—forexample, through the use of aligned through-holes 209 in the grips, inwhich a screw or other securing mechanism may be placed. Furthermore, inone embodiment, the first duct section includes a male alignmentfeature, and the second duct section includes a female alignment featureconfigured to receive the male alignment feature. Such a self-alignmentfeature assists in connecting the duct sections.

Duct structure 101 (referring to FIG. 3) includes a duct section 202 andan interconnect structure that includes one or more pins 302 on itsouter diameter. The inner surface of collar 208 includes a slot anddetent feature 502 that accepts pins 302, thereby effecting a lockedcondition. In the locked state, a sealing force between the first andsecond duct structures (104, 124) is substantially equal to apredetermined value. That is, unlike a simple threaded connection—whichcan exhibit a wide range of possible rotational positions and connectionforces—the present invention incorporates a locking mechanism having aknown sealing pressure and/or force.

Referring to FIG. 6, a locking feature 603 includes a slot 602configured to accept external pin when collar 208 is moved parallel tothe longitudinal axis of duct section 204. A detent 604 (e.g., adepression or other structure configured to accept a pin) is configuredto accept the external pin when collar 208 is rotated and placed in thelocked state. More particularly, referring to FIGS. 7 and 8, pin 302enters slot 602 when the two interconnect structures are aligned, andthen seats within detent region 604 when rotated to the locked position.It will be understood that any number of pins and corresponding pinslots may be incorporated into the inner surface of collar 208.

When in the locked state, a compressive force 702 results between pin302 and collar 208. As collar 208 is mechanically coupled to ductsection 204 (via a collar stop), a corresponding compressive force 802occurs between duct sections 204 and 202 equal to the sum of all pinforces. In a preferred embodiment, a gasket, O-ring, or other suchsealing layer is 803 provided between duct sections 204 and 202.Compressive force 702 (and 802) may be selected in accordance withapplicable design standards. In one embodiment, for example, _pins areused, and the dimensions of locking feature 603 are selected such thatthe resultant force in a locked state is between approximately 40 and 50N. It will be appreciated, however, that the invention is not solimited, and that the desired sealing force may be arrived at usingstandard mechanical engineering principles—e.g., finite-elementmodeling, closed-form structural analysis, and/or empirical testing.

In general, a method for fabricating the illustrated duct interconnectsystem includes: (1) creating or otherwise providing a digital model ofthe first duct structure; (2) providing a digital model of the secondduct structure; and (3) forming, via a direct manufacturing procedure,physical models corresponding to the first duct structure and the secondduct structure as specified by the digital models.

The digital models used to represent the various duct structures may becreated using any suitable three-dimensional CAD system. Such systemsand corresponding model data files are well known in the art. Thecomponents may be created as a single multi-component data file, or asindividual data files.

With respect to the step of forming the physical models from the digitalmodels, direct manufacturing generally refers to the direct creation ofa scale model of a part or assembly using three-dimensional computerdata. Direct-manufacturing techniques include, for example,stereolithography (SLA), selective laser sintering (SLS), laminatedobject manufacturing (LOM), fused deposition modeling (FDM), and solidground curing (SGC).

In one embodiment, the various duct components are fabricated using SLS.In this method, a work area includes a supply of powder (e.g., a metal,plastic, or composite powder), which is supplied by one or more powdermagazines. A laser and scanning mirror are used to trace out (andthermally fuse) thin layers corresponding to predefined layers of thecomputer model, while a platform within the work area moves downward (bythe thickness of one layer), layer by layer, until the entire device iscomplete. This method has certain advantages when applied to capturedcollars, as the layer planes can be defined such that the longitudinalaxis of the duct and interconnect component is normal to the layerplanes. The powder then acts to support the growing layers of thecollar, which is disconnected topologically from the duct (104, 124)itself. With standard SLA processes, which take place in a fluid,additional support structures would be required to hold the capturedcomponent in place during manufacturing.

It should also be appreciated that the exemplary embodiment or exemplaryembodiments are only examples, and are not intended to limit the scope,applicability, or configuration of the invention in any way. Rather, theforegoing detailed description will provide those skilled in the artwith a convenient road map for implementing the exemplary embodiment orexemplary embodiments. It should be understood that various changes canbe made in the function and arrangement of elements without departingfrom the scope of the invention as set forth in the appended claims andthe legal equivalents thereof.

1-12. (canceled)
 13. A duct connection system comprising: adirect-manufactured first duct structure including a first duct sectionhaving a passage for conveying a substance and a first interconnectcomponent moveably and captivity coupled to the duct section; and adirect-manufactured second duct structure including a second ductsection having a passage for conveying the substance and a firstinterconnect component configured to enter a locked state with the firstinterconnect component such that a sealing force between the first andsecond duct structures is substantially equal to a predetermined value.14. The duct system of claim 13, wherein the first interconnectcomponent and the second interconnect component each include a secondarylocking mechanism.
 15. The duct system of claim 13, wherein the firstinterconnect component is captively coupled to the first duct sectionvia at least one collar stop integral to the first duct section, andwherein the first interconnect component includes a collar configured toseat adjacent the collar stop.
 16. The duct system of claim 15, whereinthe first duct section includes two collar stops, and said firstinterconnect structure is rotateably and translationally coupled to thefirst duct section within a spatial range defined by the collar stops.17. The duct system of claim 13, wherein the first duct section includesa male alignment feature and the second duct section includes a femalealignment feature configured to receive the male alignment feature. 18.The duct system of claim 13, wherein the first interconnect structureincludes at least one grip structure.
 19. The duct system of claim 13,wherein the second interconnect component includes at least one externalpin, and the first interconnect component includes: a slot configured toaccept the external pin when the first interconnect component is movedparallel to a longitudinal axis of the first duct section; a detentconfigured to accept the external pin when the first interconnectcomponent is substantially rotated about the longitudinal axis to enterthe locked state.
 20. The duct system of claim 13, wherein the firstduct structure and the second duct structure comprise a materialselected from the group consisting of plastic and metal.